Genetically Modified TFPI And Method Of Making The Same

ABSTRACT

The present invention provides long half life genetically modified TFPI sequences (LTFPI) for anticoagulation. On the genetically modified TFPI sequence, the lysine at the carboxy-terminal sites 241, 254, 260 and 261 are replaced by alanin and the amino acid asparagine at glycosylation sites 117, 167, 228 and the amino acids serine and threonine at glycosylation sites 174 and 175 are substitutionally mutated. The present invention also provides methods of making the LTFPI through high efficient LTFPI expression from yeast production system.

FIELD OF INVENTION

The present invention relates to genetically modified TFPI sequences, and more particularly, genetic modified long half life TFPI sequences capable of protein expression in at least yeast cell.

BACKGROUND OF INVENTION

Tissue factor pathway inhibitor (TFPI) is a serine protease inhibitor synthesized primarily by vascular endothelial cell. It functions as an anticoagulant, regulating tissue factor (TF) induced cascade of blood coagulation.

Under physiology condition, TF triggers extrinsic pathway of blood coagulation during hemostasis. TF binds factor VIIa, which is a serine protease, and forms a complex with it. The complex in turn catalyzes the conversion of another inactive protease factor X into the active protease factor Xa and subsequently activating the entire extrinsic pathway of blood coagulation.

However, TF may function undesirably under pathologic condition. It is believed that the extrinsic pathway of blood coagulation triggered by TF plays a major role in thrombogenesis associated with atherosclerosis, particularly under the condition when an atheromatous plaque ruptures. TF triggered blood coagulation also plays negative roles under other pathological conditions such as myocardial infarction, ischemia, cerebrovascular disease, pulmonary thromboembolism, deep vein thrombosis, DIC and sepsis.

TFPI is a natural inhibitor to TF and blocks the extrinsic pathway of blood coagulation. TFPI inhibits factor Xa (FXa) directly, and inactivates the activity of the complex formed by factor VIIa-TF (FVIIa-TF), either with TF in suspension or with TF expressed on the surface membranes of perturbed endothelial cells, thereby stopping the cascade process of extrinsic pathway.

Structurally, wild type TFPI is a protein with molecular weight of 42-48 KD. The protein has three N-glycosylation sites on 117, 167, 228 on it. During its expression in yeast, the protein may have one more potential glycosylation site on 174 or 175.

The TFPI molecular weight varies due to the difference of sugar moiety side chains on the glycosylation sites of the protein. Glycosylation sites and sugar moieties attaching on the sites vary in different species.

The precursor TFPI molecule includes a 28 amino acid residues signal peptide. After cleavage, it gives a mature protein with 276 amino acid residues, including the N terminal which is rich in acidic amino acid residues and is highly negative in charge, followed by 3 tandem Kunitz protease inhibitory domains and a carboxyl terminal (C terminal) which is rich in basic amino acid residues and is highly positive in charge. The 3 tandem Kunitz domains are called K1, K2 and K3 respectively. K2 domain binds Factor Xa (FXa) directly and suppresses its activity. K1 domain binds Factor VIIa/TF (F VIIa/TF) via TF-Factor VIIa complex, resulting in the formation of the quaternary complex TF/FVIIa/TFPI/FXa, which is devoid of enzymatic activity, and inhibiting blood coagulation. The function of K3 domain remains unknown.

It has been an avid research field to utilize TFPI's function as a natural anticoagulant to block blood coagulation and treat thrombogenesis such as atherosclerosis in patients.

For example, U.S. Pat. No. 5,888,968 discloses a pharmaceutical composition containing TFPI for patients suffering from in E. coli sepsis. TFPI may also be used to treat blood coagulation and lower cholesterol (Effect of Cholesterol Lowering on Intravascular Pools of TFPI and Its Anticoagulant Potential in Type II Hyperlipoproteinemia, Arteriosclerosis, Thrombosis, and Vascular Biology. 1995; 15:879-885.)

One of the major obstacles of clinical application of wild type TFPI as an anticoagulation drug is that natural TFPI's half life is short, seriously limiting its application clinically.

The other problem is that the yield of TFPI in lab production is low and unstable. TFPI is currently produced in prokaryotic expression system and eukaryotic expression system. E coli expression system expresses TFPI in inclusion bodies (U.S. Pat. No. 5,212,091, US patent application publication 20050037475). Complex processes such as renaturing the protein which is a process folding the protein according to its natural 3-dimensional structure from human source, have to be employed in order to obtain active TFPI protein after the product is expressed in a prokaryotic system. The final product yield of active TFPI in a prokaryotic system is low because of the after expression processes.

Eukaryotic expression systems such as CHO (Chinese hamster Ovary cell), BHK (Baby Hamster Kidney cell), mouse C127 and yeast Saccharomyces cereuisiae (Characterization of Human Tissue Factor Pathway Inhibitor Variants Expressed in Saccharomyces cereuisiae, The Journal Of Biological Chemistry, Vol. 268, No. 18, Issue of June 25, pp. 13344-13351, 1993) have the advantage of producing folded TFPI protein, and are currently used in lab production of TFPI. However, the protein obtained from this method is just a protein having 1-161 amino acid residues, not a full length TFPI. Furthermore, some of the eukaryotic expression systems are troublesome, with low quantity of active TFPI expression and high cost. On the other hand, no document shows that TFPI can be expressed in Pichia.pastoris. Some research indicates that Pichia.pastoris system can not be used to express TFPI.

Therefore, several issues have to be addressed before active TFPI can be used in clinical practice. Long half life TFPI (LTFPI) with no immunogenesis has to be developed, and current eukaryotic expression systems need to be improved to produce high quality and stable TFPI.

SUMMARY OF THE INVENTION

One objective in accordance with the present invention is to provide a method to produce the optimized DNA sequence of TFPI which can be expressed and translated into LTFPI in yeast cell.

Another objective is to provide a genetically modified TFPI which has long half life and therefore is capable of inhibiting TF and blocking blood coagulation.

In one aspect of the invention, the invention advantageously provides a genetically modified TFPI DNA sequence which is optimized according to the sequence of three adjacent nucleotides constituting the genetic codons preferred by yeast; meanwhile the codon of the lysine at the carboxy-terminal sites 241, 254, 260 and 261 are replaced by the codons of alanin and the codons of the amino acid asparagine at glycosylation sites 117, 167, 228 and the codons of the amino acid asparagine at glycosylation sites 174 and 175 are also substitutionally mutated.

In another aspect of the invention, provided is a pharmaceutical composition for anticoagulation comprising a pharmaceutically effective amount of a genetically modified TFPI sequence wherein the lysine at the carboxy-terminal sites 241, 254, 260 and 261 are replaced by alanin and the amino acid asparagine at glycosylation sites 117, 167, 228 and the amino acid asparagine at glycosylation sites 174 and 175 are substitutionally mutated.

Yet, in another aspect of the invention, provided is a method of producing genetically modified TFPI comprising: (a) providing an optimized mutant TFPI DNA sequence which is capable of expression in a yeast cell; (b) recombining the optimized mutant TFPI sequence with a plasmid of the yeast cell; (c) transforming the plasmid into the yeast cell; (d) culturing the transformed yeast cell; (e) collecting the optimized mutant TFPI from supernatant of the cultured yeast cell; and (f) separating and purifying the collected mutant TFPI.

Additional features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying figures, which together illustrate, by way of example, features of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 a shows diagram of 10 steps of synthesizing long half life TFPI (LTFPI) by overlap-extension PCR (O-E PCR) from 10 pairs of primers (primer 10a, 10b through 1a, 1b).

FIG. 1 b shows electrophoresis of sequence segments synthesized by each step of overlap-extension PCR.

FIG. 2 shows electrophoresis result of detecting positive transformant in Pichia.pastoris.

FIG. 3 shows SDS-PAGE result of induced expression of LTFPI.

FIG. 4 shows SDS-PAGE result of LTFPI expression vs. inducing time of the expression.

FIG. 5 shows the activity of LTFPI in term of prothrombin time determined by dPT assay.

FIG. 6 shows the relationship of diluted prothrombin time vs. concentration of purified LTFPI polypeptide under 10 times diluted PT reagent and 50 times diluted PT reagent.

DETAILED DESCRIPTION OF THE INVENTION

In accordance with one embodiment of the present invention, long half life TFPI (LTFPI) is developed by genetically modifying wild type TFPI, such as mutating and substituting genetic codons of the original DNA sequence of wild type TFPI to overcome the obstacle of short half life of wild type TFPI.

TFPI is catabolized primarily in the liver. The C terminal of TFPI binds low density lipoprotein receptor-related protein (LRP) on liver cell membrane, then TFPI/LRP complex is internalized into the liver cell and degraded. TFPI degradation and elimination is highly correspondent to its C terminal sequence structure, and its binding to LRP is the key to start the process (The Carboxy Terminus of Tissue Factor Pathway Inhibitor Is Required for Interacting with Hepatoma Cells In Vitro and In Vivo, J. Clin. Invest. Volume 95, April 1995, 1773-1781).

The wild type TFPI C terminal sequence sites 241, 254, 260 and 261 have basic amino acid residue lysine. Lysine is positively charged and plays a crucial role in binding to LRP on liver cell membrane. The binding to LRP starts the process of TFPI internalization into the liver cell for degradation.

One embodiment of this invention is to provide a genetically modified LTFPI by replacing the positively charged lysine residues on TFPI C terminal sequence sites 241, 254, 260 and 261 with neutral amino acid residue alanin, by way of substitute mutation of wild type TFPI DNA sequence. Since amino acid residues alanin is neutral and is able to prevent TFPI C terminal from binding to LRP, the process of TFPI internalization into the liver cell for degradation is blocked and the half life of TFPI is prolonged. Therefore LTFPI is produced.

In additional to address the problem of short half life of wild type TFPI, currently research works are in the direction of: 1) Searching and producing modified LTFPI with better anticoagulation property. Particular attentions are focused on K1 and K2 domains since they are known to bind to FVIIa and FXa, and are critical to anticoagulation; 2) Producing naturally folded and low immunogenic TFPI for pharmaceutical application; and 3) Developing a high efficiency, low cost eukaryotic expression system to produce the LTFPI. More mutations on wild type TFPI sequence are attempted. Substitute mutation on Kunitz domain I of TFPI-2 is disclosed to produce plasmin inhibitor for clinical application (US patent application publication 20090018069). U.S. Pat. No. 5,589,359 discloses a chimeric protein providing equivalent or better anticoagulation property, while reducing glycosylated moieties on the Kunitz domains. The process of glycosylation on LTFPI protein (adding side chain sugar moieties onto the protein) and the extent of glycosylation (the number and characteristics of the sugar moieties of the added side chain) of LTFPI in yeast are different from the process and extent in human endothelial cells. It is discovered in this invention that mutating the glycosylation sites on LTFPI DNA sequence and completely eliminating sugar moiety side chains on the protein produce a new mutant LTFPI with anticoagulation effect approximately 3 times potent than that of wild type TFPI (Example 4 of the specification of the invention, mutant LTFPI activity is determined by comparison with the activity of standard from ACTICHROME TFPI Activity Assay Kit produced by American Diagnostica Inc.). Sugar moiety side chains on TFPI are immunogenic. Glycosylation sites on TFPI protein produced by yeast differ from glycosylation sites on TFPI protein produced by human cell, and the subsequent sugar moiety side chain attachments to the protein via glycoslation in yeast are different from that of TFPI synthesized in human endothelial cell naturally in terms of positions and characteristic. Because of the immunogenesis caused by glycosylation differences, TFPI produced from yeast cell can not be used as part of pharmaceutical composition in clinic application. Besides, the folding and forming of three dimensional structure of LTFPI produced by yeast expression are also different from that of TFPI synthesized in human endothelial cell naturally, since the sugar moiety side chains on the protein influence the folding and the forming of three dimensional structure of the protein. In order to solve both immunogenic and folding problems, according to this invention, LTFPI expressed in cultured yeast is mutated at all of the glycosylation sites. The LTFPI is devoid of any sugar moiety side chain attachment and is folded correctly in terms of three dimensional protein structure. Therefore, the new mutant LTFPI completely eliminated sugar moiety side chains produced by expression of genetically modified TFPI DNA sequence in yeast cell is not immunogenic. Thus, a pharmaceutically effective amount of the non immunogenic LTFPI can be used in a composition to treat pathological conditions such as thrombogenesis caused by plaque ruptures in atherosclerosis, myocardial infarction, ischemia, cerebrovascular disease, pulmonary thromboembolism, deep vein thrombosis, DIC and sepsis. LTFPI produced according to this invention has the advantages of 1) naturally folded 3 dimensional protein structure, 2) non immunogenic when it is used as part of pharmaceutical drug, and 3) enhanced anticoagulation activity; 4) extended long half life.

One embodiment of the invention is to provide an optimized mutant LTFPI DNA sequence for eukaryotic expression system by mutating the three N-glycosylation sites on 117, 167, 228 and the potential glycosylation sites on 174 or 175, thereby increasing the expression rate of LTFPI in high efficiency eukaryotic expression system production. In the meantime, the mutant LTFPI produced by the system keeps or enhances its anticoagulation activity. The genetically modified TFPI DNA sequence is characterized by the condons of lysine at the carboxy-terminal sites 241, 254, 260 and 261 are substituted by condons of alanin and the condons of amino acid asparagine at glycosylation sites 117, 167, 228 and the condons of serine and threonine at glycosylation sites 174 and 175 are substitutionally mutated. Specifically, the condons of amino acid asparagines at glycosylation sites 117, 167, 228 are substituted by condons of glutamines, and the condons of amino acid serine at glycosylation sites 174 is substituted by condons of alanin, and the condons of amino acid threonine at glycosylation sites 175 is substituted by condons of alanin. An example of the mutant LTFPI DNA sequence is a sequence represented by SEQ ID NO: 1.

A series of optimization is further performed based on the sequence of TFPI (Chinese patent application number ZL 03151203.8) by using biological information sciences software (Synthetic gene designer) according to genetic codons favored by Pichia.pastoris, and is therefore suitable to be expressed in Pichia.pastoris. A numbers of new LTFPI sequences are obtained, and are screened to select the best sequence according to the criteria mentioned above (1) naturally folded three dimensional protein structure, 2) non immunogenic when it is used as part of pharmaceutical drug, and 3) enhanced anticoagulation activity). A sequence represented by SEQ ID NO: 1 which is most suitable for Pichia.pastoris expression system is selected.

Yet another embodiment of the invention is to provide an optimized eukaryotic expression system to produce LTFPI. Pichia.pastoris is a high efficiency yeast expression system used to produce naturally folded protein. Pichia.pastoris has a high growth rate and can grow in either shake flasks or a fermenter, which makes it suitable for both small and large scale productions. With its two alcohol oxidase genes, AOX1 and AOX2 which are induced by the addition of methanol, Pichia can use methanol as a carbon and energy source. Desired protein expression is under the control of the AOX1 promoter, which means that protein production is induced by adding methanol, and the desired protein is secreted into the growth medium, which greatly facilitates subsequent protein purification.

The advantage of Pichia.pastoris expression system over bacterium Escherichia coli expression system is that E. coli might produce a misfolded protein, which is usually inactive or insoluble.

The advantage of Pichia.pastoris expression system over Saccharomyces cerevisiae (baker's yeast) expression system is that Pichia can easily be grown in cell suspension in reasonably strong methanol solutions that would kill most other micro-organisms, a system that is cheap to set up and maintain. In addition, Pichia can grow to very high cell densities and, under ideal conditions, can multiply to the point where the cell suspension is practically a paste. As the protein yield from expression in a microbe is roughly equal to the product of the protein produced per cell and the number of cells, this makes Pichia of great use when trying to produce large quantities of protein without expensive equipment. Compared to other expression systems such as S2-cells from Drosophila melanogaster or Chinese Hamster Ovary cells, Pichia usually gives much better yields. Cell lines from multicellular organisms usually require complex rich media, including amino acids, vitamins and growth factors. These media significantly limit the large scale production of LTFPI.

However, the structure of the desired protein is important to whether the protein can be expressed in Pichia.pastoris system. Some protein can be expressed highly effectively in the system, while some others can not be expressed at all. Therefore, optimization of the gene (DNA) sequence which encodes the primary structure (the sequence) of the protein is highly desirable.

In one embodiment, a method of producing genetically modified TFPI by a yeast expression system such as Pichia.pastoris expression system is provided in this invention. The method starts with an optimized mutant LTFPI sequence which is capable of expression in a yeast cell. In one embodiment, the optimized mutant LTFPI DNA sequence is a sequence represented by SEQ ID NO: 1. The optimized mutant LTFPI sequence can be provided by synthesis processes, for example by overlap-extension PCR process, chemical synthesis or some other PCR-based synthesis, which synthesize nucleotide constructs. Next, the optimized mutant LTFPI DNA sequence recombines with a plasmid, then the plasmid is transformed into the yeast cell. The transformed yeast cell is cultured and LTFPI expression is induced by adding methanol into the cultural media, and the expressed LTFPI is secreted into the cultural media. The optimized mutant LTFPI from supernatant of the cultured yeast cell is collected, separated and subsequently purified. The plasmid in this method can be any plasmid such as pPICZα, pPIC3.5K and PAO815, for the yeast expression system, typically, the plasmid is pPIC9k. The yeast in the yeast expression system can be any kind of yeast such as KM71, SMD1163 and X33, typically, the yeast is Pichia.pastoris, and the Pichia.pastoris is GS115.

The step of using overlap-extension PCR to provide the optimized mutant TFPI sequence to the method of producing genetically modified TFPI is further described as the following: Several pairs of primers are prepared. Typically, 10 pairs of primers are prepared and provided according to table 1; both ends of the primers are attached with restriction endonuclease EcoRI and NotI; several steps of overlap-extension PCR are performed starting from middle position extending outward, typically, 10 steps of overlap-extension PCR are performed starting from middle position extending outward, in which the first step is performed with 10a and 10b as the primer and the template, and the subsequent steps of the overlap-extension PCR are performed using the product of the previous step as the template and corresponding primers according to table 1.

TABLE 1 PCR Step Primers Sequences 1 10a  10b  SEQ ID NO: 3 SEQ ID NO: 4 2 9a 9b SEQ ID NO: 5 SEQ ID NO: 6 3 8a 8b SEQ ID NO: 7 SEQ ID NO: 8 4 7a 7b SEQ ID NO: 9 SEQ ID NO: 10 5 6a 6b SEQ ID NO: 11 SEQ ID NO: 12 6 5a 5b SEQ ID NO: 13 SEQ ID NO: 14 7 4a 4b SEQ ID NO: 15 SEQ ID NO: 16 8 3a 3b SEQ ID NO: 17 SEQ ID NO: 18 9 2a 2b SEQ ID NO: 19 SEQ ID NO: 20 10 1a 1b SEQ ID NO: 21 SEQ ID NO: 22

FIG. 1 a depicts a diagram of typical 10 steps of synthesizing LTFPI by overlap-extension PCR (O-E PCR) from 10 pairs of primers (primer 10a, 10b through 1a, 1b). The result of the 10 steps O-E PCR is examined by electrophoresis. FIG. 1 b depicts electrophoresis result of sequence segments synthesized by each step of overlap-extension PCR: DNA standard is in Lane 1, sequence segment synthesized with primers 10a and 10b by step 1 of O-E PCR is in Lane 2, sequence segment synthesized with primers 9a and 9b by step 2 of O-E PCR is in Lane 3, sequence segment synthesized with primers 8a and 8b by step 3 of O-E PCR is in Lane 4, sequence segment synthesized with primers 7a and 7b by step 4 of O-E PCR is in Lane 5, sequence segment synthesized with primers 6a and 6b by step 5 of O-E PCR is in Lane 6, sequence segment synthesized with primers 5a and 5b by step 6 of O-E PCR is in Lane 7, sequence segment synthesized with primers 4a and 4b by step 7 of O-E PCR is in Lane 8, sequence segment synthesized with primers 3a and 3b by step 8 of O-E PCR is in Lane 9, sequence segment synthesized with primers 2a and 2b by step 9 of O-E PCR is in Lane 10, and sequence segment synthesized with primers 1a and 1b by step 10 of O-E PCR is in Lane 11, which is the completely synthesized result sequence: SEQ ID NO. 1.

The prepared copies of LTFPI sequences are screened and selected by Pichia.pastoris expression system. FIG. 2 depicts electrophoresis result of detecting positive transformant in Pichia.pastoris. DNA standard is in Lane 1, Mut^(S) transformant is in Lane 2, Lane 3, Lane 8, Lane 9 and Lane 10, Mut⁺ transformant is in Lane 4, Lane 5, Lane 6, Lane 7. GS115 from pPIC9K is in Lane 11, serving as blank control.

After methanol induction, mutant LTFPI is expressed and secreted in to supernatant of cultural media. FIG. 3 is SDS-PAGE result showing induced expression of LTFPI: Protein standard is in Lane 1, LTFPI protein before induced expression is in Lane 2 and Lane 3, LTFPI protein after induced expression is shown in Lane 4 through Lane 8.

The amount of LTFPI expressed is proportional to methanol induction time. FIG. 4 shows SDS-PAGE result of LTFPI expression vs. inducing time: Protein standard is in Lane 1, LTFPI protein expression after 12 hour induction is in Lane 2, LTFPI protein expression after 24 hour induction is in Lane 3, LTFPI protein expression after 36 hour induction is in Lane 4 and LTFPI protein expression after 48 hour induction is in Lane 5.

The anticoagulation activity of LTFPI polypeptide produced by Pichia.pastoris expression system is tested by Diluted prothrombin time (dPT) assay or chemiluminescence assay. FIG. 5 shows the activity of LTFPI in term of prothrombin time determined by dPT assay. Series 1 is control, and series 2 is the sample containing LTFPI. Prothrombin time of control (without LTFPI) is shown in PT, dPT/10, dPT/50 and dPT/100 are prothrombin times with diluting thromboplastin standard solution in a vial with balanced saline to 10 times, 50 times and 100 times respectively. Briefly, standard reaction agents are prepared by diluting thromboplastin standard solution in vials with balanced saline to 10 times, 50 times and 100 times respectively, then adding 100 μL normal person's blood plasma sample to each of the vials, 100 μL thromboplastin standard solution and 10 μL LTFPI solution (750 μg/ml) into the vials, and coagulation times are recorded. The experiments are repeated 3 times and each group of the recorded time is averaged, and the data are plotted.

FIG. 6 shows the relationship of diluted prothrombin time vs. concentration of purified LTFPI protein under 10 times diluted PT reagent and 50 times diluted PT reagent. (Series 1 is purified LTFPI protein under 10 times diluted PT reagent and series 2 is purified LTFPI protein under 50 times diluted PT reagent). The top curve is diluted prothrombin times of various concentrations of LTFPI under condition of 50 times diluted PT reagent, below curve depicts diluted prothrombin times of various concentrations of LTFPI under condition of 10 times diluted PT reagent.

Thus a nucleotide sequence represented by SEQ ID NO: 1 which can be used to express a genetically modified LTFPI protein (SEQ ID NO: 2) for anticoagulation, is prepared. The LTFPI is characterized by the codons of the lysine at the carboxy-terminal sites 241, 254, 260 and 261 which are replaced by the codons of alanin and the codons of amino acid asparagine at glycosylation sites 117, 167, 228 and the codons of amino acid serine and threonine at glycosylation sites 174 and 175 which are substitutionally mutated.

Further, a pharmaceutical composition for anticoagulation can be prepared which comprises a pharmaceutically effective amount of genetically modified LTFPI protein encoded by a genetically modified LTFPI sequence represented by SEQ ID NO: 1, with a pharmaceutically acceptable carrier. The lysine at the carboxy-terminal sites 241, 254, 260 and 261 of genetically modified LTFPI protein are replaced by alanin and the amino acid asparagine at glycosylation sites 117, 167, 228 and the amino acid at serine and threonine glycosylation sites 174 and 175 are substitutionally mutated.

As used herein, the term “pharmaceutically acceptable carrier” refers to a medium which does not interfere with the effectiveness of the biological activity of the active ingredient and which is not toxic to the hosts to which it is administered.

As used herein, the term “pharmacologically effective amount” refers to the amount of protein or polypeptide administered to the host that results in reduction of morbidity and mortality resulting from the condition being treated. Conditions that may be treated include thrombogenesis caused by plaque ruptures in atherosclerosis, myocardial infarction, ischemia, cerebrovascular disease, pulmonary thromboembolism, deep vein thrombosis, DIC and sepsis. The exact amount administered depends on condition, severity, subject etc., but may be determined by routine methods. The term “pharmacologically effective amount” also refers to the amount of protein or polypeptide administered to the host that prevents morbidity and mortality resulting associated with a condition. Conditions that may be prevented include thrombogenesis caused by plaque ruptures in atherosclerosis, myocardial infarction, ischemia, cerebrovascular disease, pulmonary thromboembolism, deep vein thrombosis, DIC and sepsis. The exact amount administered depends on condition, severity, subject etc., but may be determined by routine methods.

EXAMPLES Example 1 Site Mutation of TFPI and Optimization of TFPI DNA Entire Sequence

The wild type TFPI sequence is mutated to obtain the mutated TFPI, represented by SEQ ID NO: 2, which has a long half life, has no glycosylation sites and is non immunogenic. The original amino acid residues asparagine at glycosylation sites 117, 167 and 228 are replaced by amino aid residues glutamine. The original amino acid residue serine at site 174 and amino acid residue threonine at site 175 are replaced by amino aid residues alanin. The original amino acid residues lysine at terminal sites 241, 254, 260 and 261 are replaced by amino aid residues alanin.

Next, a number of genetic codons which are favored by Pichia.pastoris are generated from the mutant TFPI sequence SEQ ID NO: 2 by using biological information sciences software Synthetic gene designer.

The number of genetic codons are further undergone a series of screening processes including yeast expression and testing anticoagulation activity, from which an optimized LTFPI DNA sequence represented by SEQ ID NO: 1 is obtained.

SEQ ID NO: 2 can be expressed in Pichia.pastoris (see FIG. 3 and FIG. 4 and description in Example 2) and has substantial anticoagulation activity as shown in FIG. 5 and FIG. 6.

Example 2 LTFPI Preparation and its Property Determination (1) Obtaining LTFPI Gene

Wild type TFPI gene is used as the template, and 10 pairs of primer to optimize the genetic codons favored by Pichia.pastoris are designed (See Table 1 for primer designs).

Both ends of the primers are attached with restrictive endonuclease EcoRI sequence and NotI sequence.

Overlap-extension PCR is used to extend the primers from both sides by 10 steps of PCR reactions. In 1st step of PCR, primers 10a and 10b act as mutual template and mutual primer. In the rest steps of PCR, the product from previous PCR step is the template for the next step of PCR. For example 9a and 9b, 8a and 8b . . . and so on are used as template to extend the TFPI sequence until the end of the 10 steps of the overlap-extension PCR reactions and the entire TFPI sequence is obtained.

FIG. 1. shows the process of the steps of overlap-extension PCR. The product of PCR is recovered and is connected to T carrier (pMD19-T vector, from TaKaRa Co.) and the sequence is determined by sequencing. The final sequence product is the LTFPI gene optimized with genetic codons favored by Pichia.pastoris.

(2) Constructing Plasmid pPIC9K-LTFPI for Yeast Expression

Invitrongen Corporation's pPIC9K is used as yeast expression carrier. Yeast containing LTFPI gene (clones that are sequenced correctly) with T carrier is cultured in shake flasks. The plasmid is extracted and cleaved by double restriction endonuclease EcoRI and NotI. The expression vector is also cleaved by double restriction endonuclease EcoRI and NotI. After cleavage, the sequences are recovered by 1% agarose gel electrophoresis respectively. Connecting LTFPI gene sequence with pPIC9K, and the recombinant pPIC9K-LTFPI plasmid is obtained.

(3) Electrical Transformation of Pichia.pastoris GS115

Recombinant plasmid pPIC9K-TFPI is cleaved with SalI restriction endonuclease to get completely linearized recombinant plasmid.

The linearized recombinant plasmid is extracted with phenol/chloroform, and is purified with ethyl alcohol precipitation. The purified and precipitated linearized recombinant plasmid is then dissolved in sterilized double distilled water.

Ten μL of the above linearized recombinant plasmid (10˜20 μg) sample is added by 80 μL competent Pichia.pastoris GS115 and is mixed well, then the mixture is changed over to ice-cold 0.2 cm electrical transforming cup, and put on ice-bathing for 5 min.

Electric shock transformation parameters are set to: Voltage 1500V, capacitance 25 μF, resistance 200Ω;

The mixture is electric shocked one time, and 1 mL ice-cold 1 mol/L Sorbitol is added immediately, mixing well, then 600 μL of the transformate fluid is taken and spread onto MD plate (1.34% YNB, 4×10-5% Biotin, 2% Dextrose, 1.5% Agar). The plate is cultured at 30 degree C. for 48 h until the growth of the monoclonal colony.

(4) Screening the Multi-Copy Positively Transformated Yeast Monoclonal Colony

Monoclonal yeast colonies from MD plate are selected and transferred to 96 holes cell cultural board, each of the holes of the cultural board contains 200 μL YPD cultural media, and the yeast is cultured at 30 degree C. for 24 h.

Ten μL cultured yeast is transferred to a new 96 holes cell culture board, each of the holes containing 190 μL YPD culture media, and is cultured at 30 degree C. for 24 h.

The previous steps are repeated 1 more time.

Multiple copies of 2 μL cultured yeast are transferred to YPD plates containing 0, 0.5, 1.0, 2.0, 4.0 g/L G418 respectively. Then the yeast is cultured at 30 degree C. until the monoclonal colony grows.

(5) Determining the Phenotype of Transformed Monoclonal Yeast

Monoclonal yeast from highly concentrated G418-YPD plate (approximately 107 cells) are selected. The yeast is inoculated to 20 μL 0.25% SDS solution, mixing well, then the solution is heated to 90 degree C. for 3 min. The solution is centrifuged, 1 μL of the supernatant is taken as template for PCR reaction with upstream and downstream primers.

Total PCR reaction system is 50 μL, including 1% Triton X-100.

PCR Reaction Condition:

The sample is at 95 degree C. denature for 2 min; at 95 degree C. denature for 60 second, at 55 degree C. annealing for 60 second, at 72 degree C. extending for 120 second, repeat the reactions for 30 cycles. Final step of PCR: the sample is at 72 degree C. extending for 5 min. Then the PCR product is taken out and kept at 4 degree C.

Based on the PCR result, the phenotype of transformed monoclonal yeast is determined:

Sample displays one band only (492 bp plus exogenous gene fragment 852 bp=1344 bp), the phenotype of transformed monoclonal yeast (Mut^(S)) is slow methanol user.

Sample displays two bands (the above described one band plus a 2.2 kb band), the phenotype of transformed monoclonal yeast (Mut⁺) is fast methanol user. FIG. 2. shows the experiment result.

(6) Inducing the Expression of Recombinant LTFPI in Pichia.pastoris

Pichia.pastoris containing multi-copy of positive monoclonal LTFPI from highly concentrated G418-YPD plate is selected and inoculated onto 5 mL BMGY cultural media, shaking culture 30 degree C.×250 r/min×12 h, grows to OD₆₀₀=5˜6.

The cultural media is collected and centrifuged. The pellet from centrifugation is washed with sterilized distilled water two times, then is inoculated into BMMY cultural media to induce the expression of recombinant LTFPI in Pichia.pastoris.

Additional methanol 0.3% is supplied to the cultured Pichia.pastoris once every 8 hour. Cultured Pichia.pastoris is induced by methanol for 48 hours.

FIG. 3 shows the induced expression.

FIG. 4 shows the relationship between desired protein expression and the inducing time.

(7) LTFPI Fermentation Expression

Mut⁺ type multi-copy LTFPI positive monoclonal Pichia.pastoris colony is selected and inoculated into 5 mL YPD cultural media

The cultural media is shake cultured at 30 degree C.×250 r/min for 12 h, and first-level seed culture is obtained.

The first-level seed culture is inoculated into 200 mL BMGY cultural media (1% Yeast Extract, 2% Peptone, 100 mmol/L Potassium Phosphate, 1.34% YNB, 4×10-5% Biotin, 1% Glycerol), The cultural media is shake cultured at 30 degree C×250 r/min for 16 h, to OD₆₀₀=5˜6, and second-level seed culture is obtained.

The second-level seed culture is inoculated into 4 L low salt fermentation cultural media, of which each liter contains 0.93 g CaSO₄.2H₂O, 18.2 g K2SO₄,7.27 g MgSO₄, 26.7 mL 85% H₃PO₄, 4.13 g KOH, 40 g Glycerol, 1.47 g Sodium citrate tribasic dihydrate, 2 mL PTM1 solution, pH adjusted to 5.0 with 28% ammonia.

Fermentation Cultural Condition is as Following:

Temperature 30 degree C., stirring speed 600 r/min, oxygen dissolved 35%, automatically adding ammonia to maintain pH5.0.

The media is cultured continuously for 18 h to OD₆₀₀=70˜80, till oxygen dissolved in the media rises quickly, and glycerol is exhausted from the media, then 50% glycerol is added to the media at the speed 80 mL/h, for time 2˜3 h, until the cultural media is OD₆₀₀=150˜160, addition of glycerol to the media is stopped. Wait until all the glycerol in the media is exhausted completely, then start to add methanol immediately during the first 2-3 hours, Set the feed rate to 3.6 ml/hr per liter initial fermentation volume, When the culture is fully adapted to methanol utilization, and is limited on methanol feeding, maintain the lower methanol feed rate under limited conditions for at least 1 hour after adaptation before doubling the feed. The feed rate is then doubled to ˜7.3 ml/hr/liter initial fermentation volume. After 2 hours at the 7.3 ml/hr/liter feed rate, increase the methanol feed rate to ˜10.9 ml/hr per liter initial fermentation volume. This feed rate is maintained throughout the remainder of the fermentation.

After methanol inducing expression for 40 hours, the fermentation is stopped, and the cultural media is collected from the fermentation pot, and the collected cultural media is centrifuged immediately.

The supernatant is collected and purified after centrifugation, and the precipitated Pichia.pastoris is separated.

The fermentation parameter is as follows: Temperature 30 degree C., oxygen capacity is controlled to 35±5%, pH=5.0, stirring speed is correspondent to DO (Dissolved Oxygen).

Example 3 Purification Technique (1) Concentration Via Ultra Filter

Collected 18 L of supernatant from the fermentation cultural media is centrifuged, and is filtered through Millipore 50 KD ultra filter unit, then it is further concentrated through 8 KD ultra filter unit to 0.5 L, the supernatant is concentrated approximately 40 times and becomes superfiltri-concentrated fluid after the filtering concentration process.

(2) Desalinization Via Gel Filtration

Super-filtri-concentrated fluid is added to Sephadex X-100 column (after 20 mmol/L PB (pH7.0) balanced) and passes through the column, then the column is eluted with PB at the speed of flow 8 ml/min, and active peaks are collected.

(3) Q-Sepharose Fast Flow Column Chromatography

Active peaks collected from gel filtration is collected and is added to Q-Sepharose F.F column (Pharmacia Corporation) balanced with 20 time of column volume equilibrium liquid (20 mmol/L PB pH7.0), which is pre-balanced with 50 mmol/L PB (pH 7.0) and passes the column. Anticoagulation active parts are collected after the column filtration.

(4) Heparin Sepharose CL-6B Chromatography

Desired peaks are collected and are purified on heparin affinity chromatographic column, the eluted peak components are analyzed, and the sample protein is quantified with BCA-Protein Quantitative Analysis Kit method.

the sample undergoes 12% SDS-PAGE electrophoresis, then it is stained by Coomassie brilliant blue.

The sample purity is analyzed by scanning

The sample is packaged, freeze-dried, and stored under −80 degree C.

Chromatograph operations in method of this invention disclosure are all conventional operation.

Example 4 LTFPI Activity Testing

(1) Diluted Prothrombin Time (dPT) to Determine LTFPI Activity

Anticoagulation activity of LTFPI is determined by Dilute prothrombin time.

Thromboplastin standard solution is diluted with balanced saline (physiological saline) to 10, 100, 200 and 500 times, then is stored under 37 degree C. Blood plasma samples from a normal person, each of them is 100 μL, are added to 100 μL thromboplastin standard solution with various concentrations, then 10 μL protein solution with various concentrations is added into each of the blood plasma samples.

The samples are cultured in 37 degree C. for 1 min, and 10 μL CaCl₂ solution (250 mmol/L) is added into each of the samples,

The blood plasma coagulation time is recorded.

Taking 3 experiments data an averaging them to get mean values, and recording the experimental result,

All reagents in the experiment are preheated at 37 degree C., and the entire experiment is completed in 2 hours.

FIG. 5 shows purified LTFPI polypeptide activity against control using diluted prothrombin time assay.

FIG. 6 shows the relationship of prothrombin time vs concentration of purified LTFPI polypeptide under 10 times diluted PT reagent and 50 times diluted PT reagent.

(2) Determining LTFPI Activity by Chemiluminescence Assay

The first Kunitz domain of TFPI is able to bind to FVIIa/TF complex, the second Kunitz domain of TFPI is able to bind to FXa and forms inactive FVIIa/TF/TFPI/FXa complex. After LTFPI is cultured with TF/FVIIa and FX, the activity of remaining TF/FVIIa can be determined by color substrate Spectrozyme FXa, thus the activity of LTFPI can be deducted indirectly. After purification the activity of LTFPI detected is 0.6 unit/ml, which is equal to 3 times of the activity of the standard. 

1. A method of producing genetically modified TFPI comprising: (a) providing an optimized mutant LTFPI DNA sequence which is capable of expression in a yeast cell; (b) recombining the optimized mutant LTFPI DNA sequence with a plasmid of the yeast cell; (c) transforming the plasmid into the yeast cell; (d) culturing the transformed yeast cell; (e) collecting the optimized mutant LTFPI from supernatant of the cultured yeast cell; and (f) separating and purifying the collected mutant LTFPI.
 2. The method of producing genetically modified TFPI of claim 1, wherein the plasmid is pPIC9k.
 3. (canceled)
 4. The method of producing genetically modified TFPI of claim 3, wherein Pichia.pastoris is GS115.
 5. (canceled)
 6. The method of producing genetically modified TFPI of claim 1, wherein the step of providing the optimized mutant LTFPI DNA sequence comprises at least one step of overlap-extension PCR.
 7. The method of producing genetically modified TFPI of claim 1, wherein the step of providing the optimized mutant LTFPI DNA sequence comprises: (a) providing 10 pairs of primers according to table 1; (b) attaching restriction endonuclease EcoRI and NotI onto both ends of each said primers; (c) performing 10 steps overlap-extension PCR started from middle position extending outward: (i) performing the first step with 10a and 10b as the primer and the template; (ii) performing the subsequent step of the overlap-PCR using the product of the previous step as the template and corresponding primers according to table
 1. 8. A nucleotide sequence for anticoagulation comprising a genetically modified TFPI sequence wherein codons of lysine at the carboxy-terminal sites 241, 254, 260 and 261 are replaced by codons of alanin and codons of amino acid asparagine at glycosylation sites 117, 167, 228 and codons of amino acids serine and threonine at glycosylation sites 174 and 175 are substitutionally mutated.
 9. (canceled)
 10. A synthesized polypeptide optimized for eukaryotic expression system, wherein said polypeptide is capable of anticoagulation comprising: a synthesized Long-half-life Tissue Factor Pathway Inhibitor (LTFPI) polypeptide represented by SEQ ID NO: 2 which is mutated from human wild type Tissue Factor Pathway Inhibitor (TFPI) at sites of lysine at the carboxy-terminal sites 241, 254, 260 and 261 replaced by alanine and amino acid asparagine at glycosylation sites 117, 167, 228 and amino acids serine and threonine at glycosylation sites 174 and 175 substitutionally mutated by amino acid alanine.
 11. A pharmaceutical composition for anticoagulation comprising a pharmaceutically effective amount of a genetically modified Long-half-life Tissue Factor Pathway Inhibitor (LTFPI) polypeptide represented by SEQ ID NO: 2 which is mutated from human wild type Tissue Factor Pathway Inhibitor (TFPI) wherein the lysine at the carboxy-terminal sites 241, 254, 260 and 261 are replaced by alanine and the amino acid asparagine at glycosylation sites 117, 167, 228 and the amino acids serine and threonine at glycosylation sites 174 and 175 are substitutionally mutated by amino acid alanine.
 12. (canceled)
 13. A method for treating coagulation comprising administering to a host a pharmaceutically effective amount of a genetically modified Long-half-life Tissue Factor Pathway Inhibitor (LTFPI) polypeptide represented by SEQ ID NO: 2 wherein the lysine at the carboxy-terminal sites 241, 254, 260 and 261 are replaced by alanine and the amino acid asparagine at glycosylation sites 117, 167, 228 and the amino acids serine and threonine at glycosylation sites 174 and 175 are substitutionally mutated by amino acid alanine.
 14. The method of claim 13, wherein the coagulation comprising thrombogenesis associated with atherosclerosis, under the conditions when an atheromatous plaque ruptures including myocardial infarction, ischemia, cerebrovascular disease, pulmonary thromboembolism, deep vein thrombosis, DIC and sepsis. 